US 20050205302 A1
An apparatus and method for isolating a downhole tool section from hydraulic and mechanical noise. Anchoring grippers are used in conjunction with a fluid diverter valve to anchor the tool section to a borehole wall and divert fluid flowing in the drill string away from sensitive test equipment during formation testing.
68. A downhole tool for acquiring a parameter of interest, the tool being conveyed into a well borehole on a drill string having a rotatable bit at a distal end thereof, the tool comprising:
a) a test device coupled to the drill string for determining the parameter of interest;
b) a plurality of extendable gripper elements disposed on the drill string uphole of the test device, the plurality of extendable gripper elements forcibly engaging the borehole wall above the test device to anchor at least a portion of the drill string to reduce mechanical noise at the test device; and
c) a diverter valve coupled to the drill string uphole of the test device, the diverter valve diverting drilling fluid into the annulus to reduce hydraulic noise at the test device.
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i) an extendable probe adapted to admit formation fluid into the test device; and
ii) a sensor for sensing a characteristic of the admitted fluid, the sensed characteristic being used in part to determine the parameter of interest.
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82. A system for acquiring a downhole parameter of interest while drilling a borehole through a formation, the system comprising:
a) a drill string having a rotatable bit at a distal end thereof;
b) a test device coupled to the drill string, the test device including a sensor for measuring a desired downhole characteristic and for providing an output signal representative of the measured characteristic;
c) a plurality of extendable gripper elements disposed on the drill string uphole of the test device, the plurality of extendable gripper elements forcibly engaging the borehole wall above the test device to anchor at least a portion of the drill string to reduce mechanical noise at the test device;
d) a diverter valve coupled to the drill string uphole of the test device, the diverter valve diverting drilling fluid into the annulus to reduce hydraulic noise at the test device; and
e) a processor receiving and processing the output signal, the processed signal being indicative of the parameter of interest.
83. The system of 82, wherein the processor is coupled to the drill string at a downhole location, the system further comprising a transmitter for transmitting the processed signal to a surface location.
84. The system of 82, wherein the processor is located at a surface location the system further comprising a transmitter for transmitting the output signal to the to the processor for surface processing.
85. The system of 82, wherein the processor is coupled to the drill string at a downhole location, the system further comprising a downhole memory device for storing the processed signal.
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100. A method of isolating a downhole test device from noise, comprising:
a) conveying a drill string into a well borehole, the drill string having a rotatable bit at a distal end thereof and an inner bore for conveying drilling fluid from a surface location to the drill bit;
b) anchoring a drill string portion to the borehole wall using a plurality of extendable gripper elements disposed on the drill string uphole of the test device, the plurality of extendable gripper elements forcibly engaging the borehole wall above the test device such that the drill string portion is anchored radially, axially and circumferentially while the borehole wall is engaged by the plurality of extendable gripper elements;
c) diverting drilling fluid into an annulus surrounding the drill string portion using a diverter valve to reduce hydraulic noise at the test device; and
d) obtaining a desired characteristic using a sensor disposed on the anchored drill string portion.
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This is a continuation-in-part patent application of co-pending U.S. patent application Ser. No. 09/703,645 filed on Nov. 1, 2000 and titled “Modified Formation Testing Apparatus with Borehole Grippers and Method of Formation Testing”, the application being hereby fully incorporated herein by reference.
1. Field of the Invention
This invention relates to the testing of underground formations or reservoirs. More particularly, this invention relates to a method and apparatus for isolating a downhole test tool from vibration and noise due to heave and/or drilling fluid circulation during formation testing.
2. Description of the Related Art
While drilling a well for commercial development of hydrocarbon reserves, several subterranean reservoirs and formations are encountered. In order to discover information about the formations, such as whether the reservoirs contain hydrocarbons, logging devices have been incorporated into drill strings to evaluate several characteristics of these reservoirs. Measurement-while-drilling systems (hereinafter MWD) have been developed that contain resistivity, nuclear and other logging devices which can constantly monitor formation and reservoir characteristics during drilling of well boreholes. The MWD systems can generate data that include information about the presence of hydrocarbon, saturation levels, and formation porosity. Telemetry systems have been developed for use with the MWD systems to transmit the data to the surface. A common telemetry method uses a mud-pulsed system, an example of which is found in U.S. Pat. No. 4,733,233 incorporated herein by reference. MWD systems provide real time analysis of the subterranean reservoirs.
Commercial development of hydrocarbon fields requires significant amounts of capital. Before field development begins, operators desire to have as much data as possible in order to evaluate the reservoir for commercial viability. Despite the advances in data acquisition during drilling using the MWD systems, it is often necessary to conduct further testing of the hydrocarbon reservoirs in order to obtain additional data. Therefore, after the well has been drilled, the hydrocarbon zones are often tested by other test equipment.
One type of post-drilling test involves producing fluid from the reservoir, collecting samples, shutting-in the well and allowing the pressure to build-up to a static level. This sequence may be repeated several times for different reservoirs within a given borehole. This type of test is known as a “Pressure Build-up Test.” One of the important aspects of the data collected during such a test is the pressure build-up information gathered after drawing the pressure down. From this data, information can be derived as to permeability and size of the reservoir. Further, actual samples of the reservoir fluid are obtained and tested to gather Pressure-Volume-Temperature data relevant to hydrocarbon distribution in the reservoir.
The drill string is often retrieved from the well borehole to perform these tests in an operation known as tripping. A different tool designed for the testing is then run into the well borehole. A wireline is then used to lower a test tool into the well borehole. The test tool sometimes utilizes packers for isolating the reservoir. Alternatively, a wire line can be lowered from the surface, into a landing receptacle located within a drill string test tool, establishing electrical signal communication between the surface and the test assembly. Regardless of the type of test tool and type of communication system used, the amount of time and money required for retrieving the drill string and/or running a second test tool into the borehole is significant. Further, if the borehole is highly deviated, a wire line tool is difficult to use to perform the testing.
Various MWD tools have been developed to allow for the pressure testing and fluid sampling of potential hydrocarbon reservoirs as soon as the borehole has been drilled into the reservoir, without removal of the drill string. These MWD tools also reduce the risks associated with pressure kick, because the drilling fluid pressure can be monitored and maintained better when tripping is avoided.
The typical MWD tool, however, suffers in that vibrations caused by flowing drilling fluid, mud pumps, drilling motors and surface equipment are transmitted to the test device through the drill string or even directly in the case of flowing drilling fluid. These vibrations often adversely affect test results, because the downhole instrumentation can be too sensitive to operate effectively in mechanically noisy environment.
Another problem is associated with vertical movement known as heave encountered when drilling in an offshore environment. Heave movement can cause pressure leaks where probe sealing pads and packers engage the borehole wall to form a seal. Heave movement can also result in excessive wear on soft materials used for sealing against the borehole wall. Although such heave is normally associated with offshore drilling, any unwanted vertical movement while a seal is engaged with the borehole wall can damage the seal material or cause unwanted leaks. Therefore, the use of the term heave is not meant to limit the usefulness of the present invention to offshore drilling environments. The present invention addresses the need to have a MWD tool that provides protection to sensitive test devices and protects soft sealing materials from unwanted movements that cause excessive wear on such materials.
A formation testing method and a test apparatus are disclosed. The test apparatus is mounted on a work string for use in a well borehole filled with fluid. It can be a work string designed for drilling, re-entry work, or workover applications in either on or offshore drilling operations. The work string is preferably adapted for conveying into highly deviated holes, horizontally, or even uphill. The work string preferably includes a Measurement While Drilling (MWD) system and a drill bit, or other operative elements.
One aspect of the present invention provides a downhole tool for acquiring a parameter of interest. The tool being conveyed into a well borehole on a work string having a rotatable bit at a distal end thereof. The tool includes an independently extendable gripper element disposed on the work string, wherein the extendable gripper element forcibly engages the borehole wall to anchor at least a portion of the drill string radially, axially and circumferentially while the borehole wall is engaged by the gripper element. A diverter valve is coupled to the drill string either above or below the gripper element to divert drilling fluid into the annulus. A test device is coupled to the work string for determining the parameter of interest.
In another aspect of the present invention a system for acquiring a downhole parameter of interest while drilling a borehole through a formation includes a drill string having a rotatable bit at a distal end thereof. An independently extendable gripper element is disposed on the drill string to forcibly engage the borehole wall to anchor at least a portion of the drill string radially, axially and circumferentially while the borehole wall is engaged by the extendable gripper element. A diverter valve is preferably coupled to the drill string above the grippers to divert drilling fluid into the annulus. A test device is coupled to the drill string portion and includes a sensor for measuring a desired downhole characteristic and for providing an output signal representative of the measured characteristic. A processor receives and processes the output signal, the processed signal being indicative of the parameter of interest.
A method of isolating a downhole test device from noise is also provided. The method includes conveying a drill string into a well borehole, the drill string having a rotatable bit at a distal end thereof and an inner bore for conveying drilling fluid from a surface location to the drill bit. A drill string portion is anchored to the borehole wall using an independently extendable gripper element. The method includes diverting drilling fluid above the anchored drill string portion using a diverter valve, and obtaining a desired characteristic using a sensor disposed on the anchored drill string portion.
The gripper elements may be incorporated on the work string or on a non-rotating sleeve. The grippers are extendable and are used to engage the borehole wall. Once the borehole wall is engaged, the grippers anchor the work string or non-rotating sleeve such that the work string or non-rotating sleeve remains substantially motionless during a test, i.e. to prevent movement radially, axially and circumferentially while the borehole wall is engaged by the gripper element. The advantage of anchoring the tool is increased useful life of soft components such as pad members and packers and to reduce noise caused by vibrations associated with the work string that adversely affect sensitive test equipment and test data.
An advantage of the present invention includes use of the pressure and resistivity sensors with the MWD system, to allow for real time data transmission of those measurements. Another advantage is that the present invention allows obtaining static pressures, pressure build-ups, and pressure draw-downs with the work string such as a drill string in place and in an extremely quiet environment free of vibration and movement.
For a detailed understanding of the present invention, references should be made to the following detailed description of the preferred embodiment, taken in conjunction with the accompanying drawings, in which like elements have been given like numerals and wherein:
FIGS. 1A-B are elevation views of the apparatus of the present invention as it would be used with a floating drilling rig;
FIGS. 4B-C show alternative embodiments of the gripper element of
FIGS. 5A-G show various textures for a gripper surface for increasing friction between the gripper and borehole wall;
Incorporated in the drill string 106 above the drill bit 108 is a tool 116. The tool 116 includes a test device 114 for testing formation fluid or other properties of a traversed reservoir 118. The tool 116 is a portion of the overall work string 106 and includes one or more gripper elements 120 a and 120 b to anchor a portion 106 a of the work string 106. In a preferred embodiment at least one gripper element 120 a is located above the test device 114, and a diverter valve 122 is disposed above or uphole of the upper gripper element 120 a. As will be described in more detail later, one embodiment includes a diverter valve below an upper gripper element 120 a to operate a force multiplier.
The gripper elements 120 a/120 b are extendable to engage the borehole wall 104. Once engaged the gripper elements are forcefully pressed against the wall to anchor the portion 106 a of the work string 106, which might contain sensitive test devices 114. Such anchoring isolates the test device 114 from unwanted vibrational and other mechanical noise while formation tests are performed. The isolation is particularly desirable when the test device includes sensitive test elements such as a nuclear logging instrument. Another desirable aspect of anchoring the test portion is protecting from excessive wear soft materials such as seals used to isolate an area of the borehole wall. The gripper elements operate to anchor the drill string portion radially, axially and circumferentially while tests are performed. As used herein, anchoring means to forcefully couple a device or work string portion to the borehole wall to restrain the anchored portion from movement in axial, radial and/or circumferential directions. Such anchoring prevents vertical motion from destroying the seals and prevents pressure leaks by ensuring the sealing pads stay in place.
The tool 116 further includes a sensor system 124 that incorporates various sensors 126 useful for in situ formation testing. Examples of such sensors include pressure sensors, flow sensors, nuclear magnetic resonance (“NMR”) sensors, resistivity sensors, porosity sensors, etc. . . . The tool can also include devices for sampling and testing formation fluid such as a sampling probe and/or packer. The tool can be incorporated into a drill stem tester, which is a large volume test device. The particular sensor and test device used is chosen based on the desired test. The present invention is useful in any such test using any such sensor where it is desirable to isolate the test device from mechanical and/or hydraulic noise.
As depicted in
Communication between downhole and surface equipment of the Earth can be effected via the work string 106 in the form of acoustic energy, pressure pulses through annular fluids or other methods well known in the art. In most cases, the transmitted information will be received at the surface via a 2-way communication interface 210. The data thus received will be delivered to a surface computer 212 for interpretation and display.
Command signals may be sent down the fluid column by the communications interface 210 to be received by the downhole communications interface 206. The signals so received are delivered to the downhole microprocessor/controller 204. The controller 204 will then signal the appropriate valves and pumps for operation as desired.
A bi-directional communication system as known in the art can be used as the interface 206. The purpose of the two-way communication system or bi-directional data link being to receive data from the downhole tool and to be able to control the downhole tool from surface by sending messages or commands. In one embodiment the only command is to initiate testing and the downhole controller conducts a desired test autonomously thereafter.
Data measured from the downhole tool 116 is preferably transmitted to the surface in order to utilize the measured data for real-time decisions and monitoring the drilling process. The data typically relate to measurements that are obtained from the subsurface formation, such as formation pressure information, information about optical properties or resistivity of the fluid, annulus pressure, pressure build-up or draw-down data, etc. The tool preferably transmits information that used to control the tool during its operation. For instance, information about pressure inside packers versus pressure in the annulus might be monitored to determine seal quality, information about fluid properties from the optical fluid analyzer or the resistivity sensor might be used to monitor when a sufficiently clean fluid is being produced from the formation, or status information pertaining to completion of operational steps might be monitored so that the surface operator, if required, can determine when to activate the next operational step. One example could be that a code is pulsed to surface when an operation is completed, for instance, activation of packer elements or extending a pad or other device to engage contact with the borehole wall. This data, or code, is then used by the operator to control the operation of the tool. Additionally, the downhole tool could transmit to the surface information concerning the status of its health and information pertaining to the quality of the measurements.
The valve 300 further includes one or more flow valves 312 for diverting the fluid flowing in the main channel to the borehole annulus. This allows continued fluid flow above or uphole of the seal 306 to operate hydraulic components and downhole motors. When the main channel is sealed and the flow valves 312 are open, then any component downhole of the seal 306 is substantially isolated from hydraulic noise generated by fluid flow while allowing continued flow above the seal 306.
In one embodiment the valve is positioned above a packer 128 to isolate the test device or sensor system 124 from pressure variations and hydraulic noise in the annulus between the tool and borehole wall while diverter valve is diverting fluid. In one embodiment the valve is placed above an upper gripper 120 a as shown in
The gripper element 400 includes a housing 404 and one or more high-force pistons 406. One or more gripper pads 408 are positioned on the pistons 406 so that the pistons 406 extend to forcefully press the pad 408 against the borehole wall 104. The pad 408 will typically press through mudcake build-up on the borehole wall to anchor against the underlying formation rock.
Anchoring force should be understood to be greater than the force required to merely provide back-up to an extendable probe used to sample formation fluid. The gripper, however, could be positioned to engage the borehole wall at the same depth as a sampling probe without damaging the probe. For example, two gripper elements can be angularly positioned +/−90 degrees from an extendable probe to provide anchoring according to the present invention as well as providing back-up force for the sampling probe without damaging the probe.
Various embodiments of the gripper element 400 can be used to provide effective anchoring. The embodiment of
In one embodiment the pad 408 is a tapered pad and generally circular with a shallow conical shape. The pad is pressed into the mudcake for gripping the borehole wall, and the conical shape enhances the ability to disengage the mudcake after a test. If the pad becomes stuck due to pressure differential or other cause, a movement of the drill string will help disengage the pad.
FIGS. 5B-G show various textures for a gripper surface 502 for increasing friction between the gripper and borehole wall. Exemplary yet non-limiting textured surfaces shown in FIGS. 5B-G can be either raised or indented patterns in the surface 502 of the pad 500. The surface pattern can be diamond 504, raised points 506, ridges (or grooves) 508, dimples 510, cross-hatch 512, and/or circular 514 patterns.
Referring still to
The gripper 400 can be disposed on the drill string 106 either above or below the diverter valve 300. Those skilled in the art with the benefit of this disclosure can easily determine how to best operate the gripper for the particular design chosen. For example, a gripper mounted below the diverter valve can be hydraulically operated using high pressure fluid in the interior channel of the tool by engaging the gripper before operating the diverter valve. Alternatively, the diverter valve can be fitted with a valve in the seal 306 to direct some fluid above the seal to the gripper pistons below the seal while still inhibiting fluid flow through the interior channel. A fluid force multiplier, which is known, can be used to provide additional force to effect anchoring. It is also contemplated to use a pump, either above or below the diverter valve to pump high pressure fluid directly to the gripper pistons.
A pump 618 and at least one measurement sensor 620 such as a pressure sensor are disposed in the tool section 600 for taking and measuring samples of formation fluid. A pad sealing element 622 is disposed on the extendable probe 614, and a port 624 provides fluid communication to the pump 618 and pressure sensor 620. This embodiment further shows that the extendable probe 614 can be mounted on a stabilizer 616 to reduce travel length for extending the probe 614.
During drilling operations, drilling would be momentarily stopped for testing a formation. A command to open the diverter valve 608 may be issued from a surface location or from the controller 204 disposed in the tool section 600. The diverter valve 608 then opens in response to the command to allow continued mud circulation through the drill string 602 for operating the power supply 606. The grippers 612 are then extended to engage the borehole wall to anchor the tool section. Once the tool section 600 is anchored in place the probe 614 is extended to seal a portion of borehole and is isolated from hydraulic and mechanical vibrations and movement by use of the grippers 612 and diverter valve 608.
Once the pad 622 is in sealing contact with the borehole wall, the pump is activated to reduce the pressure at the port 624. When the pressure is reduced at the port 624 formation fluid enters the port. If samples are desired, the fluid is directed by internal valves to the sample chamber section 610. Measurements of fluid characteristics, such as formation pressure, are taken with the sensor 620. The communication system 604 is then used to transmit data representative of the sensed characteristic to the surface. The data may also be preprocessed downhole by the downhole processor 204 of
A pump 718 and at least one measurement sensor 720 such as a pressure sensor are disposed in the tool section 700. The pump 718 and pressure sensor 720 are as described above and shown if
There could be any number of variations to the above-described embodiments that do not require additional illustration. For example, alternate embodiments could be the embodiments of
The foregoing description is directed to particular embodiments of the present invention for the purpose of illustration and explanation. It will be apparent, however, to one skilled in the art that many modifications and changes to the embodiment set forth above are possible without departing from the scope of the invention. It is intended that the following claims be interpreted to embrace all such modifications and changes.